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Process and system for converting carbonaceous feedstocks into energy without greenhouse gas emissions

a technology of carbonaceous feedstocks and conversion systems, applied in the direction of combustible gas production, sustainable manufacturing/processing, electrochemical generators, etc., can solve the problem of requiring an air separation plant, producing a problem source of carbon dioxide and other greenhouse gases, and reducing the efficiency of the process. , to achieve the effect of high hydrogen content and high efficiency

Active Publication Date: 2006-11-07
RAVEN SR INC
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Benefits of technology

[0018]The present process avoids the difficult path of attempting to strip and capture the carbon dioxide from stack gases and without attempting to carry out separate chemical reactions of carbon dioxide to attempt to produce useful products. The process and system of the present invention uses unique gasification technology combined with fuel cells to generate electricity at high efficiency. This is accomplished by taking advantage of a very unique property of fuel cells—namely, the two anodic and cathodic reactions are separated by an electronically conducting membrane that keeps the product gases separate. In this way, a combustible feed gas can be fully oxidized in the first half-cell of the fuel cell without being commingled wit the final products of the air reduction in the second half-cell electrode, i.e., N2. For example, in coal gasification, synthesis gas is formed consisting predominantly of hydrogen and carbon monoxide. This synthesis gas is fed into the first half-cell, i.e., the anode or negative terminal side, of the fuel cell, such as the solid oxide or molten carbonate types, where it is oxidized to water and carbon dioxide. These gases are not diluted by the typical nitrogen remaining after oxygen reduction in the second or remaining half-cell, i.e., the cathode side or positive tenninal, of the fuel side. Nitrogen and combustion gases are commingled when combustion air is used in boilers or furnaces. Thus, in the fuel cell, the synthesis gas (syngas) is oxidized without being comnbusted with air and without being diluted by other gases. The fuel cell-produced water and carbon dioxide are simply separated from each other by condensing the liquid water and allowing carbon dioxide to return to the gasifier. The carbon dioxide being injected into the high temperature gasifier undergoes a reaction with the high temperature carbonaceous feed to form more carbon monoxide, repeating the cycle.
[0019]By means of the present process and system, the carbon dioxide in the fuel cell is easily kept separate from the air side and any nitrogen. This carbon dioxide can be recycled back to the gasifler in nearly pure form. Likewise steam in pure form can be recycled as well in different amounts under gasifier control system requirements to maintain the ideal hydrogen to carbon monoxide ratio in the range of about 1.2 to about 1.75. This steam helps maintain a high hydrogen content in the gasifier so that a portion of the gasifler-produced syngas car be used downstream in a chemical reactor such as a Fischer-Tropsch reaction system for the production of a variety of useful chemicals ranging from methanol to paraffin waxes. These in turn are used to make useful chemicals such as naplitha, gas oil, and kerosine, or agricultural chemicals or carbide abrasives. The latter are not over burned in their lifecycle, and they sequester the carbon forever. Thus, the carbon monoxide is used to produce useful chemicals instead of discarding the valuable carbon source in the carbon dioxide. The carbon balance of the plant is maintained such that the mass of carbon input in the waste feed is equal to the carbon mass leaving the plant as valuable hydrocarbon products; not carbon dioxide.

Problems solved by technology

The burning of fossil fuels in boilers to raise high temperature, high-pressure steam that can be used to power turbo-electric generators produces a problem source of carbon dioxide and other greenhouse gases, e.g. methane, ozone and fluorocarbons.
However, to date none of these clean coal programs aim to eliminate the emissions of carbon dioxide and other greenhouse gases.
Efforts to use pure oxygen in power plants and gasification systems to avoid the diluting effects of nitrogen and to achieve higher efficiency suffers from the unacceptable cost of requiring an air separation plant and the problems of excessive temperatures in oxygen-fed combustion turbo-generators.
Today there is worldwide concern that the atmospheric buildup of carbon dioxide and other greenhouse gases will start to have serious environmental consequences for the earth's tropospheric temperature, global rainfall distribution, water balance, severe weather storms, and similar consequences.
This has, indeed, been a very large challenge with poor successes as summarized by the review papers; see Michele Aresta, and Eugenio Quaranta, “Carbon Dioxide: A Substitute for Phosgene,” Chem. Tech. pp.
Trying to scrub the CO2 from stack gases and trying to chemically react the recovered CO2 clearly is not the right path of research because of the technical difficulty and the process expense of reacting carbon dioxide.

Method used

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  • Process and system for converting carbonaceous feedstocks into energy without greenhouse gas emissions
  • Process and system for converting carbonaceous feedstocks into energy without greenhouse gas emissions
  • Process and system for converting carbonaceous feedstocks into energy without greenhouse gas emissions

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Embodiment Construction

[0034]Preferred Embodiment of Process for Hydrogen Fuel Cell Energy Without Production of Unwanted Greenhouse Gases Using a Kiln.

[0035]FIG. 1 illustrates a specific embodiment of the process and system of the present invention in which a carbonaceous waste feed material is passed via inlet line 10 to a non-catalytic high temperature, gas-phase reactor 12 and is converted into synthesis gas at high temperature in the range of about 700° to about 1600° C. (1300–2900° F.). Preferably, a rotary kiln is used as gasifier 12 having outlet 14 to remove the buildup of solids. The syngas produced in gasifier 12 that leaves through outlet line 18 is then split downstream into two flow lines 20 and 22. The syngas in flow line 20 enters fuel cell 26 at port 28. The second syngas stream is passed via flow line 22 to Fischer-Tropsch catalytic reactor 30.

[0036]Preferably gasifier 12 is a slightly inclined horizontal rotary kiln that is heated externally and is called an “indirectly heated rotary ki...

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Abstract

The process and system of the invention converts carbonaceous feedstock such as coal, hydrocarbon oil, natural gas, petroleum coke, oil shale, carbonaceous-containing waste oil, carbonaceous-containing medical waste, carbonaceous-containing hazardous waste, carbonaceous-containing medical waste, and mixtures thereof into electrical energy without the production of unwanted greenhouse emissions. The process and system uses a combination of a gasifier, e.g., a kiln, operating in the exit range of at least 700° to about 1600° C. (1300–2900° F.) to convert the carbonaceous feedstock and a greenhouse gas stream into a synthesis gas comprising mostly carbon monoxide and hydrogen without the need for expensive catalysts and or high pressure operations. One portion of the synthesis gas from the gasifier becomes electrochemically oxidized in an electricity-producing fuel cell into an exit gas comprising carbon dioxide and water. The latter is recycled back to the gasifier after a portion of water is condensed out. The second portion of the synthesis gas from the gasifier is converted into useful hydrocarbon products.

Description

[0001]This application is a continuation-in-part of application U.S. Ser. No. 10 / 184,264 filed Jun. 27, 2002; now abandoned now published as Publication No. 2003 / 0022035 on Jan. 30, 2003. This application is related to and contains common subject matter with U.S. Ser. No. 09 / 186,766 filed Nov. 5, 1998; now U.S. Pat. No. 6,187,465 issued Feb. 13, 2001 (the '465 patent), which claims the benefit of U.S. provisional application Ser. No. 60 / 064,692 filed Nov. 7, 1997. This application is not a continuation-in-part of the latter application, U.S. Ser. No. 09 / 186,766, as stated in the parent application, U.S. Ser. No. 10 / 184,264.[0002]This invention relates to non-greenhouse gas emitting processes and systems which accomplish the conversion of a carbonaceous gas stream and a greenhouse gas into a synthesis gas comprising hydrogen and carbon monoxide without the need for expensive catalysts and or high pressure operations.BACKGROUND OF THE INVENTION[0003]The burning of fossil fuels in boil...

Claims

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Application Information

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IPC IPC(8): H01M8/06
CPCC10J3/005C10J3/10C10J3/24H01M8/0612H01M8/0668C10J2300/1246C10J2300/1612C10J2300/1646C10J2300/1659Y02E20/16Y02E60/50Y02E20/18Y02P30/00
Inventor GALLOWAY, TERRY R.
Owner RAVEN SR INC
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